Voice only phone and method of operation

ABSTRACT

A voice only phone and method of operation; the voice only phone having a microprocessor configured to operate an interactive voice respondent (IVR) that is used to verbally interact with a user. The IVR allows the user to interact with the voice only phone to place calls, receive calls, receive text messages, and respond to text messages using only voice commands. Furthermore, the IVR allows for the dynamic creation of a voice phone book that is progressively updated. In order to better recognize the voice of the user, the voice only phone creates a voice profile through a voice recognition setup sequence, wherein the user is prompted to dictate a plurality of audible calibration inputs. Once the voice profile is created, the user is able to place phone calls by either dictating a contact name or a plurality of digits for a phone number.

The current application claims a priority to the U.S. Provisional Patent application Ser. No. 62/017,338 filed on Jun. 26, 2014.

FIELD OF THE INVENTION

The present invention relates generally to mobile phones. More specifically, the present invention is a voice only phone that utilizes an interactive virtual respondent for voice recognition and operation via voice commands.

BACKGROUND OF THE INVENTION

Section 255 of the Communications Act, as amended by the Telecommunications Act of 1996, requires that cell phone manufacturers and service providers do all that is “readily achievable” to make each product or service accessible. Although, there are tons of “smart” phones with millions of features on the market, there is still no single phone designed specifically for blind and visually impaired people. Smartphones require touching and looking on screen to manage the phone book, which is difficult for visually impaired people. While some smartphones do have limited support for visually impaired people, such device are typically very expensive as they include touchscreens, cameras, etc., many components of which are of little to no use to the visually impaired. As a result, visually impaired users end up paying for tons of features that are not used. Furthermore, almost all smartphones have challenges with voice recognition accuracy, accents, and specific words.

The prevalent use of smartphones has also led to an increase in the number of people texting and driving. Texting and driving is dangerous, as in the United States alone over 5,000 drivers die each year due to an accident involving texting. This a major area of concern for many parents, especially those of children just learning to drive. Apart from the dangers of texting and driving, more and more parents want to give their kids simple phone where they can simply make a call to check how their kid is doing without fear that an expensive phone can be broken, lost or that their kid will get addicted to games on a smartphone. Many parents do not feel that their child is responsible yet for an expensive phone, or fear that their child will get addicted to technology but still want to be able to communicate with their child.

As previously mentioned, most smartphones are expensive devices. Not only are smartphone expensive, but they are also very fragile and prone to breaking easily. As such, cases and screen protectors are often used to protect smartphones from being dropped, scratched, etc. Some cases are even designed to prevent water damage, which smartphone are very susceptible to. Such cases and screen protectors are often expensive accessories, thus further increasing the cost of owning a smartphone. In addition to having fragile components, smartphones also often deal with battery issues, as large amounts of energy are consumed in order to power the components, such as the touchscreen and backlights.

Therefore it is the object of the present invention to provide a voice only phone and a method for operating the voice only phone using an interactive virtual respondent (IVR). The voice only phone is simplistic in nature, having no touchscreen and only one external control button in the form of an activation switch. The IVR allows a user to interact with the voice only phone to place calls, receive calls, receive text messages, and respond to text messages using only voice commands. Furthermore, the IVR allows for the dynamic creation of a voice phone book that is progressively updated. In order to better recognize the voice of the user, the voice only phone creates a voice profile through a voice recognition setup sequence, wherein the user is prompted to dictate a plurality of audible calibration inputs. Once the voice profile is created, the user is able to place phone calls by either dictating a contact name or a plurality of digits for a phone number.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flowchart depicting the steps for calibrating the voice only phone and making a call with the voice only phone;

FIG. 2 is a flowchart thereof, further depicting steps for calibrating each of a plurality of audible calibration inputs in order to update a voice profile;

FIG. 3 is a flowchart thereof, further depicting steps for making a phone number selection using a contact name;

FIG. 4 is a flowchart thereof, further depicting steps for making the phone number selection using a plurality of digits;

FIG. 5 is a flowchart thereof, further depicting steps for receiving and dictating a text message;

FIG. 6 is a flowchart thereof, further depicting steps for receiving and storing a text message;

FIG. 7 is a flowchart thereof, further depicting steps for sending a subsequent voice message; and

FIG. 8 is a flowchart thereof, further depicting steps for activating a speakerphone function.

FIG. 9 is a top perspective view of the voice only phone.

FIG. 10 is a bottom perspective view of the voice only phone.

FIG. 11 is a diagram depicting the electronic connections with the microprocessor.

FIG. 12 is a diagram depicting the electrical connections with the battery.

FIG. 13 is a perspective view of the voice only phone positioned in the speakerphone dock, wherein the dock monitor is communicably coupled to the speakerphone dock.

DETAIL DESCRIPTIONS OF THE INVENTION

All illustrations of the drawings are for the purpose of describing selected versions of the present invention and are not intended to limit the scope of the present invention.

The present invention is a voice only phone 1 and a method for operating the voice only phone 1. The voice only phone 1 comprises a phone case 2, an electronics assembly 3, a battery 4, and an activation switch 5. An interactive virtual respondent (IVR) is operated through the electronics assembly 3, allowing a user to verbally communicate with the voice only phone 1, thus eliminating the need for a touchscreen or any other external controls aside from the activation switch 5. The simplistic nature of the voice only phone 1 leads to increased life of the battery 4, as the battery 4 does not need to power any energy exhaustive components. Additionally, less processing power is needed (and thus less power) do to the nature of the functions made available through the voice only phone 1.

In reference to FIG. 9-10, the phone case 2 comprises a first shell 21, a second shell 22, and a bumper 23. Together, the first shell 21, the second shell 22, and the bumper 23 form an elongated enclosure for housing the electronics assembly 3, the battery 4, and the activation switch 5. The bumper 23 is perimetrically connected to the first shell 21, while the second shell 22 is perimetrically connected to the bumper 23 opposite the first shell 21; the first shell 21 forming the top half of the voice only phone 1 and the second shell 22 forming the bottom half of the voice only phone 1. In the preferred embodiment of the present invention, the first shell 21 is concave, while the second shell 22 is convex; the resulting shape increases the ergonomics of the voice only phone 1 when being held. Additionally, the curved nature of the first shell 21 and the second shell 22 aid in the buoyancy of the voice only floating, allowing the voice only phone 1 to float.

In addition to holding together the first shell 21 and the second shell 22, the bumper 23 also serves as a form of protection for the voice only phone 1 by absorbing impact forces that could occur from dropping the voice only phone 1, bumping the voice only phone 1 into a surface, etc. Furthermore, the bumper 23 can provide increased friction between another surface to prevent the voice only phone 1 from slipping, such as when positioned in a pocket. In the preferred embodiment of the present invention, the bumper 23 is constructed from rubber, however, in other embodiments of the present invention the bumper 23 can be constructed from any other material, preferably having similar high friction and pliable properties.

In reference to FIG. 11-12, the electronics assembly 3 and the battery 4 are positioned within the phone case 2; depending on the embodiment of the voice only phone 1, the activation switch 5 may also be positioned within the phone case 2. The electronics assembly 3 provides the means for communication between the user and the voice only phone 1, and communication between the voice only phone 1 and an electronic device of a subsequent user. As such, the electronics assembly 3 comprises a microprocessor 31, a speaker 32, a microphone 33, and a transceiver 34. The microprocessor 31 is configured to operate the IVR, which allows the voice only phone 1 to adapt to the unique voice of the user, and store and associate phone numbers with individual contacts.

The microprocessor 31 receives electronic signals from the microphone 33 and the transceiver 34 and outputs electronic signals through the speaker 32 and the transceiver 34. As such, the microphone 33, the speaker 32, and the transceiver 34 are electronically connected to the microprocessor 31, as depicted in FIG. 11. The microphone 33 receives voice input from the user and directs the resulting electronic signals to the microprocessor 31, the speaker 32 outputs audio based on electronic signals received from the microprocessor 31, and the transceiver 34 exchanges electronic signals between the microprocessor 31 and the electronic device of the subsequent user for voice to voice communication.

The speaker 32 and the microphone 33 are positioned adjacent to the first shell 21 and positioned opposite each other along the phone case 2. The concave nature of the first shell 21 assists in blocking out environmental noise when the voice only phone 1 is being operated, thus allowing for more precise voice recognition via the IVR. The ability to block out environmental noise also makes it easier for the user to hear from the speaker 32, particularly when the voice only phone 1 is held against the head.

The electronics assembly 3 further comprises an at least one noise cancellation microphone. The at least one noise cancellation microphone is positioned opposite the microphone 33 along the phone case 2, and opposite the speaker 32 about the phone case 2, wherein the at least one noise cancellation microphone is positioned adjacent to the second shell 22. When the user is speaking into the microphone 33, the at least one noise cancellation microphone picks up environmental noises. The noise picked up by the microphone 33 and the noise picked up by the at least one noise cancellation microphone are processed and compared by the microprocessor 31 using a noise reduction algorithm to single out the unique voice of the user from the environmental noise. As such, the at least one noise cancellation microphone is electronically connected to the microprocessor 31.

The battery 4 provides current to power the electronics assembly 3 and the activation switch 5, and as such the electronics assembly 3 and the activation switch 5 are electrically connected to the battery 4, as depicted in FIG. 12. The activation switch 5 is used to change the power state of the electronics assembly 3. The activation switch 5 can be used to power off the electronics assembly 3, wherein no current is supplied to the electronics assembly 3, thus calls cannot be sent or received and the user cannot interact with the IVR. Subsequently, the activation switch 5 can also power on the electronics assembly 3, wherein current is supplied to the electronics assembly 3.

Furthermore, the activation switch 5 can be used to toggle the electronics assembly 3 between a low power state and a high power state. In the low power state, current is only supplied to the transceiver 34 in order to receive incoming calls and in the high power state current is supplied to the entirety of the electronics assembly 3. When an electronic signal is received by the transceiver 34 in the low power state, the transceiver 34 send a signal to the microprocessor 31 to switch the electronics assembly 3 to the high power state.

In one embodiment of the present invention, the activation switch 5 is a push button, wherein the activation switch 5 is positioned though the phone case 2. More specifically, the activation switch 5 is positioned through the second shell 22, such that the activation switch 5 is accessible on the back of the voice only phone 1. When the activation switch 5 is pressed or held, the electronics assembly 3 is switched to the appropriate power state.

In another embodiment of the present invention, the activation switch 5 is a motion sensor, wherein the activation switch 5 is positioned within the phone case 2. The activation switch 5 being the motion sensor can be an accelerometer, a gyroscope, or a similar sensor that is capable of detecting the phone case 2 being shook, or otherwise disturbed. When the activation switch 5 detects that the phone case 2 is motion, the electronics assembly 3 is switched to the appropriate power state.

The present invention also utilizes a speakerphone dock 6 and a charging station. The speakerphone dock 6 is a holder into which the voice only phone 1 is positioned and with which the voice only phone 1 is communicably coupled. The electronics assembly 3 further comprises a dock monitor 35 that is communicably connected to the speakerphone dock 6 and is electronically connected to the microprocessor 31, as depicted in FIG. 11. In this way, when the voice only phone 1 is positioned within the speakerphone dock 6 as shown in FIG. 13, the dock monitor 35 is able to detect the presence of the speakerphone dock 6 and in turn activate a speaker phone function for the speaker 32 by signaling the microprocessor 31, as depicted in FIG. 8. When the voice only phone 1 is removed from the speakerphone dock 6, the dock monitor 35 detects the absence of the speakerphone dock 6 and the speakerphone function is disabled.

The dock monitor 35 provides a wireless means of communicating with the speakerphone dock 6. The dock monitor 35 is positioned within the phone case 2, such that there is no physical connection, such as a port, between the voice only phone 1 and the speakerphone dock 6. As such, there are no holes through the phone case 2 through which dust, water, etc. can enter the phone case 2 and internally damage the voice only phone 1. The dock monitor 35 can be a near field communication device, a radio-frequency identification device, an electromagnetic device, or any other device capable of detecting the close range presence of the speakerphone dock 6. The dock monitor 35 communicates with a subsequent device within the speakerphone dock 6 using the same standard as the dock monitor 35.

The charging station provides a means for wirelessly charging the battery 4. The charging station is a pad or holder onto which the voice only phone 1 is positioned, wherein the battery 4 and the charging station are electromagnetically coupled. The charging station includes a primary coil, while a secondary coil is electrically connected to the battery 4. The secondary coil can either be built into the battery 4 or be a standalone component connected to the battery 4. When current is supplied to the primary coil and the voice only phone 1 is positioned on the charging station, the primary coil induces a current in the secondary coil which charges the battery 4. The ability to wirelessly charge the battery 4 means that no ports or physical connectors are needed, and as such, there are no holes through the phone case 2 through which dust, water, etc. can enter the phone case 2 and internally damage the voice only phone 1.

Another feature of the voice only phone 1 is that the voice only phone 1 is waterproof. The waterproof feature of the voice only phone 1 is due mainly to the simplistic design of the voice only phone 1. As there are no holes for charging ports, data connectors, etc. the phone case 2 is substantially sealed; the bumper 23 creating a water tight seal between the first shell 21 and the second shell 22. The only holes through the phone case are for the speaker 32, the microphone 33, and the at least one noise cancellation microphone. However, the speaker 32, the microphone 33, and the at least one noise cancellation microphone are waterproof and are connected to the interior of the phone case 2, forming a watertight seal. In this way, water or other liquids are not able to penetrate the phone case 2 and damage the electronics assembly 3 or battery 4. Furthermore, is the activation switch 5 is the push button, then the activation switch 5 is also waterproof and forms a watertight seal with the phone case 2.

In order to use the voice only phone 1, the user must first create a voice profile by interacting with the IVR. The voice profile acts to calibrate the voice only phone 1, such that the IVR is able to recognize the unique voice of the user. In reference to FIG. 1, when the voice only phone 1 is activated for the first time, the microprocessor 31 initiates a voice recognition setup sequence to create the voice profile. The voice recognition setup sequence includes the steps of: dictating a calibration prompt for a plurality of audible calibration inputs through the speaker 32; receiving the plurality of audible calibration inputs through the microphone 33; and analyzing the plurality of audible calibration inputs in order to create the voice profile.

In reference to FIG. 2, the calibration prompt instructs the user to speak a specific audible calibration input from the plurality of audible calibration inputs. The voice only phone 1 first dictates the calibration prompt for the specific audible calibration input through the speaker 32, wherein the user orates the specific audible calibration input into the microphone 33. The voice only phone 1 receives the specific audible calibration input orated by the user as a first input instance, and then dictates the calibration prompt again, asking the user to repeat the specific audible calibration input. Again, the user orates the specific audible calibration input into the microphone 33, wherein the voice only phone 1 receives the specific audible calibration input as a second input instance.

In further reference to FIG. 2, once the voice only phone 1 has received the first input instance and the second input instance of the specific audible calibration input, the microprocessor 31 compares the second input instance to the first input instance. The second input instance is compared to the first input instance in order to determine whether or not the specific audible calibration input orated by the user is valid. If the second input instance does not match the first input instance, then the voice only phone 1 re-dictates the calibration prompt, telling the user to orate the specific audible calibration input again. If the second input instance matches the first input instance, then the microprocessor 31 updates the voice profile for the specific audible calibration input, such that the microprocessor 31 is able to recognize future input of the specific audible calibration input.

In the preferred embodiment of the preset invention, the plurality of audible calibration inputs includes the numbers 0 to 9, the word ‘Yes’, and the word ‘No’. The voice only phone 1 first dictates the calibration prompt for the number 0, wherein the user orates the number 0 as the first input instance and the second input instance. The microprocessor 31 then compares the first input instance and the second input instance for the number 0. If the first input instance and the second input instance match, then the microprocessor 31 updates the voice profile for the number 0 in order to recognize the number 0 in the unique voice of the user at a later time. Once the steps of the voice recognition setup sequence for the number 0 are completed, the process is then repeated for the remaining numbers and words, wherein each of the plurality of audible calibration inputs is analyzed in order to create the voice profile.

Even after the voice profile for the user has been created through the voice recognition setup sequence, the microprocessor 31 is able to dynamically adapt the voice profile. This is to account for an unintended change in tone of the unique voice of the user. For example, if the user has a cold and resultantly a raspy voice, the voice only phone 1 may repeat the voice recognition setup sequence for all or some of the plurality of audible calibration inputs. The subsequent results of the voice recognition setup sequence can be stored separately from, or meshed with the initial results of the voice recognition setup sequence in order to adapt to the change in the unique voice of the user.

Once the voice profile has been created, the user is able to verbally communicate with the voice only phone 1. Verbal interaction with the IVR allows the user to place and accept call, as well as build a dynamic voice phone book that is progressively updated as the user utilizes the voice only phone 1. In the preferred embodiment of the present invention, the prompts of the voice only phone 1 are limited to integer responses, or yes and no responses by the user. The limitation of the acceptable responses by the user allows for simplistic interaction with the IVR, which greatly improves voice recognition precision and in turn the overall user experience.

In reference to FIG. 1, each subsequent time the voice only phone 1 is activated the voice only phone 1 dictates, through the speaker 32, a call selection prompt for a phone number selection. The call selection prompt instructs the user to make the phone number selection by either saying a contact name or a plurality of digits corresponding to a phone number. The user dictates the method in which to make the phone number selection, and then either dictates the contact name or the plurality of digits. Upon receiving the phone number selection through the microphone 33, the voice only phone 1 dials the phone number corresponding to the phone number selection. In the preferred embodiment of the present invention, the call selection prompt instructs the user to say the number 1 to make the phone number selection by name, and to say the number 2 to make the phone number selection by number.

If the user chooses to make the phone number selection by name, then the user dictates the contact name through the microphone 33. The voice only phone 1 receives the contact name as the phone number selection and checks to see if the contact name is stored in memory. If the contact name is stored in memory, then the voice only phone 1 dials the phone number corresponding to the contact name. When the voice only phone 1 dials the phone number, the voice only phone 1 dictates the contact name to the user through the speaker 32. If the contact name is not stored in memory, then the voice only phone 1 initiates a sequence to program the contact name in memory as a part of the dynamic voice phone book.

In reference to FIG. 3, similar to programming the plurality of audible calibration inputs, the voice only phone 1 requires a first contact input instance and a second contact input instance in order to store the contact name. The original dictation of the contact name that initiates the programming sequence is received by the voice only phone 1 as the first contact input instance. The voice only phone 1 then dictates a contact name input prompt to instruct the user to repeat the contact name, wherein the user again speaks the contact name. The voice only phone 1 receives the contact name spoken for the second time as the second contact input instance, and then compares the second contact input instance to the first contact input instance.

In further reference to FIG. 3, if the second contact input instance does not match the first contact input instance, then the voice only phone 1 dictates the contact name input prompt for the contact name, instructing the user to again speak the contact name for the first contact input instance and the second contact input instance. If the second contact input instance and the first contact input instance match, then the voice only phone 1 dictates a number association prompt for the contact name. The number association prompt instructs the user to orate the plurality of digits to be stored with the contact name. The user then dictates the plurality of digits, wherein the voice only phone 1 receives the plurality of digits for the contact name and correspondingly stores the plurality of digits with the contact name. Once the contact name and the plurality of digits are correspondingly stored in memory, the user can use the contact name as the phone number selection by speaking the contact name once.

In reference to FIG. 4, if the user chooses to make the phone number selection by number, then the user dictates the plurality of digits through the microphone 33. The voice only phone 1 receives the plurality of digits as the phone number selection and checks to see if the sequence of the plurality of digits is stored in memory. If the sequence of the plurality of digits is stored in memory, then the voice only phone 1 dials the phone number corresponding to the plurality of digits. If the sequence of the plurality of digits is not stored in memory, then the voice only phone 1 dictates a number storage prompt, wherein the number storage prompt asks whether or not the user wants to store the plurality of digits in memory. If the user does not want to store the plurality of digits in memory, then the voice only phone 1 dials the phone number. When the voice only phone 1 dials the phone number, the voice only phone 1 dictates the plurality of digits to the user through the speaker 32. If the user wants to store the plurality of digits in memory, then the voice only phone 1 initiates a sequence to program the plurality of digits in memory as a part of the dynamic voice phone book.

In further reference to FIG. 4, to program the sequence of the plurality of digits into memory, the voice only phone 1 dictates the contact name input prompt, instructing the user to speak the contact name for the plurality of digits. If the contact name is not stored in memory, then the voice only phone 1 initiates the sequence to program the contact name in memory, wherein the voice only phone 1 receives the contact name as the first contact input instance and the second name input sequence. Upon receiving the contact name for the plurality of digits and successfully comparing the second contact input instance to the first contact input instance, the voice only phone 1 correspondingly stores the contact name with the plurality of digits. If the contact name already exists in memory, then the voice only phone 1 dictates a contact update prompt instructing the user to select between replacing the plurality of digits currently associated with the contact name and choosing a subsequent contact name. Once the contact name and the plurality of digits are correspondingly stored in memory, the user can use the contact name as the phone number selection by speaking the contact name once.

In yet further reference to FIG. 4, if the plurality of digits is less than ten digits, or is otherwise not a valid phone number, then the voice only phone 1 dictates a retry call selection prompt for the phone number selection. The retry call selection prompt asks whether or not the user would like to attempt to dictate the plurality of digits again. The user then dictates a retry response being either ‘Yes’ or ‘No’ for the phone number selection. The voice only phone 1 receives the retry response and takes the appropriate action. If the retry response is ‘Yes’, then the voice only phone 1 prompts the user to dictate the plurality of digits again. If the retry response is ‘No’, then the voice only phone 1 powers down.

When the voice only phone 1 receives a call, the user engages the activation switch 5 in order to initiate the IVR. The voice only phone then dictates either the plurality of digits of the phone number or the contact name of the phone number to the user. The voice only phone 1 then dictates a call accept prompt, wherein the call accept prompt asks whether or not the user wants to accept the call. The user then dictates a call response being either ‘Yes’ or ‘No’ for the voice message. The voice only phone 1 receives the call response and takes the appropriate action. If the call response is ‘Yes’, then the voice only phone 1 accepts the call. If the call response is ‘No’, then the voice only phone 1 rejects the call.

In reference to FIG. 5-6, the voice only phone 1 is also capable of receiving and dictating text messages. When the voice only phone 1 receives the text message from another device (e.g. using the Short Messaging Service standard), the voice only phone 1 processes the text message into a voice message through the microprocessor 31. The voice only phone 1 then dictates a message selection prompt, wherein the message selection prompt asks whether or not the user wants to listen to the voice message. The user then dictates a message response being either ‘Yes’ or ‘No’ for the voice message. The voice only phone 1 receives the message response and takes the appropriate action. In reference to FIG. 6, if the message response is ‘No’, then the voice only phone 1 stores the voice message in a message que, wherein the user can access the voice message at a later time. In the preferred embodiment of the present invention, the voice only phone 1 dictates the message selection prompt each time the voice only phone 1 is activated, if there are any voice messages in the message que.

In reference to FIG. 5, if the message response is ‘Yes’, then the voice only phone 1 dictates the voice message through the speaker 32. Once the voice message has been dictated to the user, the voice only phone 1 dictates a message reply prompt. The message reply prompt asks whether or not the user would like to send a return voice message in response to the text message. The user then dictates a message reply response being either ‘Yes’ or ‘No’ for sending the return voice message. The voice only phone 1 receives the message reply response and takes the appropriate action. In reference to FIG. 7, if the message reply response is ‘Yes’, then the voice only phone 1 prompts the user to dictate the return voice message. The voice only phone 1 receives the return voice message through the microphone 33 and then sends the return voice message to the other device. If the message reply response is ‘No’, then the voice only phone 1 powers down. In the preferred embodiment of the present invention, the return voice message is sent by the Multimedia Messaging Service standard.

The voice only phone also supports a ‘find me’ feature in which the voice only phone 1 is programmed to respond to a specific phrase. The electronics assembly 3 may further comprise a specialized microphone to be used with the ‘find me’ feature, or the microphone 33 may be used. Similar to the microphone 33, the specialized microphone is electrically connected to the microprocessor 31. Additionally, the specialized microphone is waterproof and forms a water tight seal with the interior of the phone case 2 to prevent any water or other liquids from entering the phone case 2.

The voice only phone 1 prompts the user though the IVR to orate the specific phrase into the microphone 33, or the specialized microphone configured for the ‘find me’ feature. When the voice only phone 1 receives the specific phrase through the microphone 33 or the specialized microphone, the voice only phone 1 stores the specific phrase in memory. In order to use the ‘find me’ feature, power is constantly supplied to either the microphone 33 or the specialized microphone. If the microphone 33 or the specialized microphone detect a human voice, then the microprocessor 31 is powered on. The microprocessor 31 then processes the human voice(s), searching for the specific phrase.

If the microprocessor 31 does not detect the specific phrase and the microphone 33 or the specialized microphone stop detecting human voice(s), then the microprocessor 31 powers off. If the microprocessor 31 does detect the specific phrase, then the microprocessor 31 initiates a verbal response. The microprocessor 31 signals the speaker 32 to dictate the verbal response, such that the user or another individual is able to locate the voice only phone. The ‘find me’ feature is configured to detect the specific phrase in the voice of any individual and not just the user. For example, if the specific phrase is ‘Just Phone’ and the microprocessor 31 detects the specific phrase in any voice, then the voice only phone 1 dictates the verbal response such as ‘I am here, I am here’.

Another feature of the voice only phone 1 is a low battery warning. When the battery 4 is low (e.g. 10% power, 5% power, 1%), the voice only phone 1 will announce a verbal message to the user. The verbal message can be initiated in two different ways. The first way to initiate the verbal message is by engaging the activation switch 5, after which the voice only phone 1 will dictate the verbal message indicating the battery 4 being low prior to dictating any other prompts. The second way to initiate the verbal message is if the microphone 33 or the specialized microphone detect a human voice, wherein the microphone 33 or the specialized microphone is always powered on. Upon detecting the human voice, the microprocessor 31 is powered on and the verbal message indicating the battery 4 being low is dictated.

Although the invention has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the invention as hereinafter claimed. 

What is claimed is:
 1. A voice only phone system comprising: a phone case; an electronics assembly; a battery; an activation switch; the electronics assembly comprising a microprocessor, a speaker, a microphone and a transceiver; the microprocessor being configured to operate an interactive virtual respondent; the phone case comprising a first shell, a second shell and a bumper; the bumper being perimetrically connected to the first shell; the second shell being perimetrically connected to the bumper opposite the first shell; the electronics assembly and the battery being positioned within the phone case; the speaker, the microphone, the transceiver and the activation switch being electronically connected to the microprocessor; the electronics assembly and the activation switch being electrically connected to the battery; the first shell being concavely contoured; the second shell being convexly contoured; the speaker and the microphone being positioned adjacent to the first shell; a wireless charging station for wirelessly charging the battery; the wireless charging station comprising a first coil; the battery comprising a second coil; and the first coil and the second coil being electromagnetically coupled with each other.
 2. The voice only phone system as claimed in claim 1 further comprising: the activation switch being a push button; and the activation switch being positioned through the phone case.
 3. The voice only phone system as claimed in claim 1 further comprising: the activation switch being a motion sensor; and the activation switch being positioned within the phone case.
 4. The voice only phone system as claimed in claim 1 further comprising: a speakerphone dock; the electronics assembly further comprising a dock monitor; the device dock monitor being communicably coupled to the speakerphone dock; and the device dock monitor being electronically connected to the microprocessor.
 5. A method for operating a voice only phone system as claimed in claim 1 by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method comprising the steps of: A) providing a microprocessor being configured to operate an interactive virtual respondent, a speaker, and a microphone; B) initiating a voice recognition setup sequence consisting of steps (C), (D), and (E), if the voice only activated phone is activated for the first time; C) dictating a calibration prompt for a plurality of audible calibration inputs through the speaker; D) receiving the plurality of audible calibration inputs through the microphone; E) analyzing the plurality of audible calibration inputs in order to create a voice profile; F) dictating, through the speaker, a call selection prompt for a phone number selection; G) receiving the phone number selection through the microphone; and H) dialing a phone number corresponding to the phone number selection.
 6. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 5 further comprises the steps of: dictating the calibration prompt for a specific audible calibration input from the plurality of audible calibration inputs; receiving the specific audible calibration input as a first input instance; receiving the specific audible calibration input as a second input instance; and comparing the second input instance to the first input instance.
 7. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 6 further comprises the steps of: re-dictating the calibration prompt for the specific audible calibration input, if the second input instance does not match the first input instance.
 8. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 6 further comprises the steps of: updating the voice profile for the specific audible calibration input, if the second input instance matches the first input instance.
 9. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 5 further comprises the steps of: receiving a plurality of digits as the phone number selection.
 10. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 9 further comprises the steps of: dictating a contact name input prompt for the plurality of digits, if the plurality of digits is not stored in memory; receiving a contact name for the plurality of digits; and correspondingly storing the contact name with the plurality of digits.
 11. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 9 further comprises the steps of: dictating a retry call selection prompt for the phone number selection, if the plurality of digits is less than ten digits; and receiving a retry response for the phone number selection.
 12. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 5 further comprises the steps of: receiving a contact name as the phone number selection.
 13. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 12 further comprises the steps of: receiving the contact name as a first contact input instance; receiving the contact name as a second contact input instance; and comparing the first contact input instance to the second contact input instance.
 14. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 13 further comprises the steps of: dictating a contact name input prompt for the contact name, if the second contact input instance does not match the first contact input instance.
 15. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 12 further comprises the steps of: dictating a number association prompt for the contact name, if the contact name is not stored in memory; receiving a plurality of digits for the contact name; and correspondingly storing the plurality of digits with the contact name.
 16. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 5 further comprises the steps of: receiving a text message; processing the text message into a voice message; and dictating the voice message through the speaker.
 17. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 5 further comprises the steps of: receiving a text message; processing the text message into a voice message; and storing the voice message in a message que.
 18. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 5 further comprises the steps of: receiving a subsequent voice message through the microphone; and sending the subsequent voice message.
 19. The method for operating a voice only phone by executing computer-executable instructions stored on a non-transitory computer-readable medium, the method as claimed in claim 5 further comprises the steps of: detecting a speakerphone dock; and activating a speakerphone function for the speaker. 